U.S. patent application number 10/102017 was filed with the patent office on 2003-01-30 for plasma display apparatus.
Invention is credited to Hirose, Tadatsugu, Kishi, Tomokatsu, Seo, Yoshiho, Takamori, Takahiro.
Application Number | 20030020673 10/102017 |
Document ID | / |
Family ID | 19056782 |
Filed Date | 2003-01-30 |
United States Patent
Application |
20030020673 |
Kind Code |
A1 |
Hirose, Tadatsugu ; et
al. |
January 30, 2003 |
Plasma display apparatus
Abstract
A PDP apparatus of good display quality has been disclosed,
wherein plural common electrodes and plural scan electrodes that
extend in the directions perpendicular to each other are formed on
a first substrate and plural address electrodes that respectively
make a pair with the plural common electrodes and extend in the
same direction of that thereof are formed on a second substrate. A
display cell is formed at the crossing portion of each pair of the
common electrode and the address electrode and each scan electrode,
the lit state or the unlit state of each display cell is selected
by applying a scan pulse sequentially to the scan electrode and
applying an address pulse selectively to the address electrode in
synchronization with the application of the scan pulse, and a
sustain pulse is applied to the plural common electrodes and the
plural scan electrodes.
Inventors: |
Hirose, Tadatsugu;
(Kawasaki, JP) ; Seo, Yoshiho; (Kawasaki, JP)
; Kishi, Tomokatsu; (Kawasaki, JP) ; Takamori,
Takahiro; (Kawasaki, JP) |
Correspondence
Address: |
STAAS & HALSEY LLP
700 11TH STREET, NW
SUITE 500
WASHINGTON
DC
20001
US
|
Family ID: |
19056782 |
Appl. No.: |
10/102017 |
Filed: |
March 21, 2002 |
Current U.S.
Class: |
345/60 |
Current CPC
Class: |
G09G 3/2983 20130101;
G09G 2320/0228 20130101; G09G 3/2932 20130101; G09G 3/2927
20130101; G09G 2300/0452 20130101; G09G 3/294 20130101 |
Class at
Publication: |
345/60 |
International
Class: |
G09G 003/28 |
Foreign Application Data
Date |
Code |
Application Number |
Jul 24, 2001 |
JP |
2001-223443 |
Claims
We claim:
1. A plasma display apparatus, comprising plural common electrodes
that are formed on a first substrate and extend in a first
direction, plural scan electrodes that are formed on the first
substrate and extend in a second direction perpendicular to the
first direction, and plural address electrodes that are formed on a
second substrate opposing the first substrate, extend in the first
direction, and each address electrode respectively making a pair
with each common electrode, wherein a discharge space is formed
between the first substrate and the second substrate, a display
cell is formed at the crossing portion of each pair of the common
electrode and the address electrode and each scan electrode, the
lit state or the unlit state of each display cell is selected by
applying a scan pulse sequentially to the plural scan electrodes
and at the same time applying an address pulse selectively to the
plural address electrodes in synchronization with each scan pulse,
and a sustain discharge is caused to occur in a display cell to be
lit by applying a sustain pulse between the plural common
electrodes and the plural scan electrodes.
2. A plasma display apparatus, as set forth in claim 1, wherein the
scan electrode is provided on the side near the address electrode
at the crossing portion of the common electrode and the scan
electrode on the first substrate and the common electrode is
provided under the scan electrode via a dielectric.
3. A plasma display apparatus, as set forth in claim 2, wherein the
common electrode has a step that makes a roundabout way to avoid
the scan electrode and protrudes downward at the crossing
portion.
4. A plasma display apparatus, as set forth in claim 2, wherein the
scan electrode has a step that makes a roundabout way to avoid the
common electrode and protrudes upward at the crossing portion.
5. A plasma display apparatus, as set forth in claim 2, further
comprising a dielectric layer, the width of which is almost the
same as that of the scan electrode, beneath the scan electrode.
6. A plasma display apparatus, as set forth in claim 1, wherein the
address electrode is exposed to the discharge space.
7. A plasma display apparatus, as set forth in claim 1, wherein
part of the scan electrode at the crossing portion is exposed to
the discharge space.
8. A plasma display apparatus, as set forth in claim 7, further
comprising plural pores that connect the discharge space and the
surface of the scan electrode at the crossing portion of the scan
electrode.
9. A plasma display apparatus, as set forth in claim 1, wherein the
common electrodes and the scan electrodes respectively have common
auxiliary electrodes and scan auxiliary electrodes that are
connected to the common electrodes and the scan electrodes,
respectively, and widen the common electrodes and the scan
electrodes, respectively.
10. A plasma display apparatus, as set forth in claim 9, wherein
the depths of the surfaces of the common auxiliary electrode and
the scan auxiliary electrode with respect to the surface that comes
into contact with the discharge space are the same.
11. A plasma display apparatus, as set forth in claim 1, further
comprising partition walls on the surface of the second substrate
so as to separate the address electrodes.
12. A plasma display apparatus, as set forth in claim 11, wherein
the partition walls define the interval between the first substrate
and the second substrate.
13. A plasma display apparatus, as set forth in claim 11, further
comprising spacers, which define the interval between the first
substrate and the second substrate together with the partition
walls.
14. A plasma display apparatus, as set forth in claim 1, wherein
the arrangement pitch of the plural scan electrodes is the same as
those of the plural common electrodes and the plural address
electrodes.
15. A plasma display apparatus, as set forth in claim 14, wherein
the adjacent three of the plural scan electrodes are classified
into one group, a scan pulse is applied sequentially to the
electrode of each group, and the three adjacent display cells
formed by the adjacent three scan electrodes have the same lit or
unlit state.
16. A plasma display apparatus, as set forth in claim 1, wherein
the arrangement pitch of the plural scan electrodes is three times
that of the plural common electrodes and the plural address
electrodes.
17. A plasma display apparatus, as set forth in claim 16, wherein
the common electrodes and the scan electrodes respectively have
common auxiliary electrodes and a scan auxiliary electrodes that
are connected to the common electrodes and the scan electrodes,
respectively, and widen the common electrodes and the scan
electrodes, respectively, in the vicinity of the crossing portion
and the common auxiliary electrodes and the scan auxiliary
electrodes have an elliptical shape, the length-to-width ratio of
which is, on the whole, 3:1.
18. A plasma display apparatus, as set forth in claim 1, wherein
the scan electrode runs in zigzag so that the crossing point of the
scan electrode and the common electrode forms a vertex.
19. A plasma display apparatus, as set forth in claim 1, wherein
the three display cell columns formed by the three pairs of the
common electrode and the address electrode form three different
color pixel columns, respectively.
20. A plasma display apparatus, as set forth in claim 1, wherein
the common electrodes are classified into groups by light emission
color of the display cell, each group is independently driven, and
the sustain pulse is applied in the different period for each
group.
Description
BACKGROUND OF THE INVENTION
[0001] The present invention relates to a plasma display apparatus.
More particularly, the present invention proposes a three-electrode
AC (alternate current) type surface discharge plasma display
apparatus with a new structure.
[0002] The plasma display apparatus (PDP apparatus) has been put to
practical use as a flat display and is highly regarded as a thin
high-luminance display. Among several types of the PDP apparatus,
an AC type PDP, in which the light emission display is performed by
applying a voltage waveform alternately to two sustain electrodes
to keep on causing a discharge to occur, is mostly used. A
discharge is completed 1 .mu.second to a few .mu. seconds after the
application of a pulse. Ions, which are positive charges generated
by a discharge, accumulate on the surface of the insulating layer
on an electrode to which a negative voltage is being applied, and
electrons, which are negative charges, accumulate on the surface of
the insulating layer on an electrode to which a positive voltage is
being applied.
[0003] Therefore, after wall charges are first formed on a cell to
be displayed by selectively causing a discharge to occur with a
pulse (write pulse) of a high voltage (write voltage), if a pulse
(sustain pulse or sustain discharge pulse) of a voltage lower
(sustain voltage or sustain discharge voltage) than before and of
the opposite polarity is applied, a threshold value of discharge
voltage is exceeded and a discharge is caused to occur in the cell
to be displayed because the voltage due to the wall charges
accumulated thereon is overlapped and a large voltage develops
across the discharge space. (A discharge is not caused to occur in
a cell not to be displayed, to which a write pulse has not been
applied, even if a sustain pulse is applied.) In other words, a
cell, in which wall charges have been formed once by a write
discharge, has a characteristic that a discharge is kept on by
continuing to apply a sustain pulse, the polarity of which being
alternately reversed. This is called the memory effect. Generally,
an AC type PDP apparatus performs a display by utilizing this
memory effect.
[0004] The AC type PDP apparatuses include the two-electrode type,
in which a selection discharge (address discharge) and a sustain
discharge are caused to occur by two electrodes, and the
three-electrode type, in which an address discharge is caused to
occur by utilizing a third electrode. The color PDP apparatus that
performs a gray level display excites the phosphor formed in a
discharge cell by the ultraviolet rays generated by a discharge,
but the phosphor has a drawback of being susceptible to the impact
of ions, which are positive charges generated by the discharge.
Because the above-mentioned two-electrode type has a structure in
which the phosphor is directly hit by ions, the life of the
phosphor may be shortened. To avoid this, a color PDP apparatus
generally employs the three-electrode structure that utilizes the
surface discharge. The three-electrode type further includes two
types: in one type a third electrode is formed on the same
substrate on which a first and a second electrodes that perform the
sustain discharge have been arranged, and in the other type the
third electrode is arranged on another opposing substrate. On the
other hand, when the three kinds of electrodes are formed on the
same substrate, there are two types: in one type the third
electrode is arranged over the two electrodes that perform the
sustain discharge, and in the other type the third electrode is
arranged thereunder. Still furthermore, there are two types: in one
type the visible light emitted from the phosphor is viewed
therethrough (transparent type), and in the other type that
reflected by the phosphor is viewed (reflection type).
[0005] FIG. 1 is a rough plan view of the panel to be used in the
above-mentioned three-electrode surface discharge AC type PDP
apparatus. FIG. 2 is a rough sectional view in the vertical
direction of a discharge cell of the panel in FIG. 1 and FIG. 3 is
that in the horizontal direction that shows an example of the
reflection type in which part of the sustain electrode is formed by
a transparent electrode on the panel on which the third electrode
(address electrode) is formed on another substrate different from
and opposing the substrate having the electrodes that perform the
sustain discharge.
[0006] As shown in FIG. 1, plural first electrodes (X electrodes)
12 and second electrodes (Y electrodes) 11-1 to 11-N are arranged
adjacently by turns and plural third electrodes (address
electrodes) 13-1 to 13-M are arranged in the direction
perpendicular thereto. A partition wall 14 is formed between
address electrodes. The X electrodes 12 are connected commonly. A
display cell is formed at the crossing of each pair of the X
electrode 12 and the Y electrode 11 and each address electrode 13.
Therefore, each display cell is separated in the horizontal
direction by the partition wall 14 but is continuous with the
display cells contiguous thereto in the perpendicular direction.
Therefore, the gap between the pairs of the X electrode 12 and the
Y electrode 11 is vertically widened to prevent adjacent display
cells from affecting each other.
[0007] The panel is composed of two glass substrates 21 and 29. On
the first substrate 21, the plural first electrodes (X electrodes)
12 and the plural second electrodes (Y electrodes) 11, which
correspond to the sustain electrodes and are arranged adjacently by
turns, are formed and these electrodes are composed of transparent
electrodes 22a and 22b and bus electrodes 23a and 23b. Because of
the role to allow the light reflected by the phosphor to pass
through, the transparent electrode is made of such as ITO
(transparent film the main component of which is indium oxide). The
bus electrode needs to be made of a material of a low resistance
therefore is made of Cr (chromium) or Cu (copper), because it is
necessary to avoid the reduction in voltage due to the electrical
resistance. Moreover, the bus electrode is covered with a
dielectric layer (glass) 24 and an MgO (magnesium oxide) film 25 is
formed as a protection film on the discharge surface. On the other
hand, on the second substrate 29 that opposes the first glass
substrate 21, the plural third electrodes (address electrodes) 13
are formed in the direction perpendicular to that of the sustain
electrodes (X, Y electrodes). The partition wall 14 is formed
between the address electrodes and between the partition walls,
phosphors 27 that have the light emission characteristics of red
(R), green (G), and blue (B) are formed so as to cover the address
electrode. The two glass substrates are assembled so that the ridge
of the partition wall 14 and the MgO film 25 come into close
contact with each other. The space between the phosphor 27 and the
MgO film 25 is aidischarge space 26.
[0008] The method to drive the above-mentioned three-electrode
surface discharge AC type PDP apparatus is called the
"Address/sustain discharge period separated type-write address
method". This drive method is briefly described below. In the first
reset period, each display cell is set to a uniform state. In this
reset period, all the display cells are set to a uniform state by
applying a voltage sufficiently greater than the threshold voltage
between the X electrode and the Y electrode to cause a discharge to
occur, while a fixed voltage (0 V, for example) is being applied to
the address electrode, then neutralizing the charges generated by
the discharge by making the potentials of the X electrode and the Y
electrode equal to each other. In the next address discharge
period, with a state in which a fixed voltage is being applied to
the X electrode, a scan pulse of, for example, -150 V is applied
sequentially to the Y electrode, a write pulse (of 50 V, for
example) is applied to the address electrode of a cell to be made
to emit light in synchronization with the application of each scan
pulse, and no write pulse is applied (that is, 0 V is applied) to
the address electrode of a cell not to be made to emit light. In
this way, a discharge is caused to occur in a cell to be made to
emit light and wall charges are formed on the surface of the
dielectric on the X electrode and the Y electrode, but no wall
charge is formed in a cell not to be made to emit light. In the
next sustain discharge period, with a state in which a fixed
voltage (0 V, for example) is being applied to the address
electrode, a sustain pulse is applied alternately to the X
electrode and every Y electrode. The sustain pulse has such a
voltage (180 V, for example) that a sustain discharge is caused to
occur in a cell to be made to emit light, in which the wall charges
have been formed during the address discharge period, by
overlapping the voltage due to the wall charges because the
threshold voltage is exceeded, but no discharge is caused to occur
in a cell not to be made to emit light in which no wall charge has
been formed. As the occurrence of a sustain discharge forms the
wall charges of the opposite polarity, a discharged is caused to
occur if a sustain pulse of the opposite polarity is applied
subsequently. In this way, a discharge is kept on, due to the
memory effect, by applying a sustain pulse the opposite polarity of
which is alternately changed. What contributes to the display is
this sustain discharge and, the longer the sustain discharge
period, the higher the light emission luminance is. By repeating
the above-mentioned reset period, address discharge period, and
sustain discharge period, the display is performed.
[0009] In the PDP apparatus, it is possible only to control the
display cell whether to emit light or not, but the light emission
intensity cannot be changed for each display cell. Therefore, when
the gray level display is performed, one display frame is made to
comprise plural subframes. Each subframe is composed of a reset
period, an address discharge period, and a sustain discharge
period, and the light emission intensity is varied by changing the
length of the sustain discharge period. Then, a desired light
emission luminance can be obtained by selecting the subframes to be
made to emit light in one display frame for each display cell.
[0010] The PDP apparatus comprises a drive circuit to apply a
voltage to each electrode of the panel described above, a frame
memory to convert display data into a signal appropriate for the
drive signal in the PDP apparatus, control circuits of each part,
and so on, and, as these are widely known, a description is omitted
here. Although various examples of modification to such as the
panel structure and the drive method have been proposed, no
description about these is provided here.
[0011] For the three-electrode surface discharge AC type PDP
apparatus that has been known so far, various figures of the
electrode to improve the discharge efficiency have been proposed,
but it can be said, on the whole, that the X electrode and the Y
electrode, which are the sustain electrodes, are designed so as to
extend in the same direction.
[0012] For a gas discharge display apparatus such as the PDP
apparatus that performs the image display, it is required to
prevent a discharge in a display cell from affecting adjacent
display cells to cause a discharge to occur in a cell not to be
made to emit light, and to keep on causing a discharge to occur in
a cell to be made to emit light, therefore, a structure in which
display cells are separated is needed. In the above-mentioned
three-electrode surface discharge AC type PDP apparatus, for
example, the gap between the pairs of the x electrode 12 and the Y
electrode 11 is vertically widened to prevent adjacent display
cells from affecting each other and the wall partition 14 is
provided to horizontally separate the display cells, as described
above. Such a structure, however, has the following problems. One
of them is that although the wall partition is separated
horizontally, if there exists a flaw in the wall partition, a
charge may flow to an adjacent cell, not to be made to emit light,
through it, a discharge may be caused to occur in the cell not to
be made to emit light by the charge as a trigger, and an erroneous
display may be caused. Another problem is that the gap between the
pairs of the X electrode 12 and the Y electrode 13 is vertically
widened to prevent a discharge from being caused to occur,
therefore, the vertical interval between the display cells needs to
be also widened, and as a result the density of display cells
cannot be increased.
[0013] Moreover, the panel structure of the above-mentioned
three-electrode surface discharge AC type PDP apparatus has still
another problem that since the sustain electrodes (X electrodes and
the Y electrodes) are arranged in parallel, the panel volume
becomes large and it is necessary to use a drive circuit of a
higher performance accordingly, resulting in a larger power
consumption and a higher cost.
SUMMARY OF THE INVENTION
[0014] The present invention will solve these problems and the
objective is to realize a PDP apparatus that is able to prevent an
erroneous display by defining the range of each display cell with a
structure of an electrode and has a high density of display cells,
and to reduce the power consumption and the cost.
[0015] FIG. 4 is a diagram that shows the fundamental structure of
the plasma display panel (PDP) used in the PDP apparatus of the
present invention. As shown in FIG. 4, in order to realize the
above-mentioned objective, in the plasma display apparatus of the
present invention, plural common electrodes X and plural scan
electrodes Y that respectively extend in directions perpendicular
to each other are formed on a first substrate 34, and plural
address electrodes A that extend in the same direction as that of
the plural common electrodes x corresponding thereto are formed on
a second substrate 36 that opposes the first substrate 34 and forms
a display space 37 therebetween. A display cell is formed at the
crossing portion of each pair of the common electrode X and the
address electrode A and each scan electrode Y, the lit state or the
unlit state of each display cell is selected by applying a scan
pulse sequentially to the plural scan electrodes Y and at the same
time applying an address pulse selectively to the plural address
electrodes A in synchronization with each scan pulse, and a sustain
discharge is caused to occur in a display cell to be lit by
applying a sustain pulse alternately to the plural common
electrodes X and the plural scan electrodes Y.
[0016] As shown schematically, at the crossing portion on the first
substrate 34, the common electrode X is provided under the scan
electrode Y via a dielectric layer 35 and the scan electrode Y is
arranged on the side near the address electrode A.
[0017] FIG. 5A through FIG. 5E and FIG. 6A and FIG. 6B are diagrams
that illustrate the operation of the PDP apparatus of the present
invention, and FIG. 5A and FIG. 5C are sectional views viewed from
the direction perpendicular to the scan electrode Y and FIG. 5B and
FIG. 5D are those viewed from the direction perpendicular to the
common electrode X. As in the conventional way, an erase discharge
is caused to occur by applying an erase pulse between the X
electrode and the Y electrode and all the display cells enter a
uniform state. Then, while a voltage Vx is being applied to the
common electrode, a scan pulse of voltage -Vy is applied
sequentially to the scan electrode Y and at the same time an
address pulse is applied selectively to the plural address
electrodes A in synchronization with each scan pulse. The address
pulse applies a voltage Va to a cell to be made to emit light and a
voltage 0 V, to a cell not to be made to emit light. In this way,
no discharge is caused to occur in a cell not to be made to emit
light, but a discharge is caused to occur in a cell to be made to
emit light because the voltage between the scan electrode Y and the
address electrode A exceeds the discharge start voltage, and
positive charges and negative charges are formed on the cell to be
made to emit light in the discharge space, as shown in FIG. 5A.
[0018] As described above, the voltage Vx is being applied to the
common electrode X, an electric field is formed between the common
electrode X and the scan electrode Y, and the generated positive
charges and negative charges are accumulated on the dielectric
layer 35 on the common electrode X and the scan electrode Y
according to the electric field. This is shown in FIG. 5C through
FIG. 5E. By performing this action sequentially on every scan
electrode Y, wall charges are formed on a cell to be made to emit
light in the arrangement shown in FIG. 5E.
[0019] FIG. 6A and FIG. 6B are diagrams that illustrate the
discharge start voltage between the common electrode X and the scan
electrode Y. As shown in FIG. 6A, as the common electrode X and the
scan electrode Y are perpendicular to each other, the gap d between
the electrodes at the point of the distance r from the crossing
portion can be obtained as d={square root}{square root over (2)}x
r. FIG. 6B shows the Paschen curve that represents the discharge
start voltage Vf with respect to the product Pd of the pressure P
within the discharge space and the discharge gap d. From this
diagram, it is known that the Paschen curve has the characteristic
of being convex downward and the voltage is below the voltage Vt in
the domain between Pd1 and Pd2. Since the pressure P is constant,
the domain between Pd1 and Pd2 corresponds to range of the
discharge gap between d1 and d2, corresponding to the distance
between r1 and r2 from the crossing portion. By applying the
sustain discharge voltage Vs to the scan electrode Y, a discharge
is caused to occur when the voltage due to the wall charges
accumulated on the common electrode X and the scan electrode Y is
overlapped and the voltage Vt is exceeded, and wall charges of the
opposite polarity are accumulated on the common electrode X and the
scan electrode Y. Therefore, by applying the sustain discharge
voltage Vs to the common electrode X, a discharge is caused to
occur and wall charges are accumulated. By repeating this action,
the sustain discharge is caused to occur repeatedly. As shown in
FIG. 6B, when the discharge gap d becomes larger as the distance
from the crossing portion of the common electrode X and the scan
electrode increases, the discharge start voltage also becomes
higher, therefore, a discharge is hardly caused to occur and it is
unlikely that the discharge propagates. In other words, a discharge
is caused to occur only when the distance from the crossing section
is between rl and r2.
[0020] As described above, in the plasma display apparatus of the
present invention, as the scan electrode extends in the direction
perpendicular to those of the common electrode and the address
electrode, if a voltage is applied between the scan electrode and
the common electrode or between the scan electrode and the address
electrode, the electric field intensity becomes the strongest at
the crossing portion and its vicinity and it decreases as the
distance from the crossing portion increases. Therefore, when a
discharge or a sustain discharge is caused to occur to select the
lit state or the unlit state of each display cell by applying a
voltage between the scan electrode and the common electrode or
between the scan electrode and the address electrode, the discharge
is limited to the crossing portion and its vicinity and is hardly
propagated to adjacent display cells, therefore, an erroneous
display can be avoided. Because of this, it will be possible to
remove the partition wall used conventionally, and to realize a PDP
apparatus, in which the density of display cells is high. Moreover,
since the common electrode and the scan electrode, between which a
discharge is caused to occur, are perpendicular to each other, the
volume and power consumption can be made less compared to a
conventional one in which they are parallel and at the same time
the cost can also be reduced because it is possible to use a
circuit with a lower drive performance.
[0021] When the scan electrode and the common electrode are
provided on the first substrate, they are made to form plane layers
the height of which are different from each other, and the
dielectric layer is provided therebetween. In this case, since the
volume of the crossing portion becomes large, it is designed so
that the common electrode has a step that makes a roundabout way to
avoid around the scan electrode and protrudes downward at the
crossing portion, or the scan electrode has a step that makes a
roundabout way to avoid the common electrode and protrudes upward
at the crossing portion. If such a structure is employed, it will
be possible to provide a scan electrode and a common electrode
flush with each other, on the first substrate, except for the
crossing portion.
[0022] It is possible to reduce the volume of the crossing portion
by providing a structure of a dielectric on the crossing portion of
the common electrode and forming the scan electrode thereon
instead. Moreover, it is also preferable to provide the structure
of a dielectric along the entire length of the scan electrode
thereunder.
[0023] The address electrode can be exposed to the discharge
space.
[0024] As described above, a discharge is caused to occur in a part
a certain distance away from the crossing portion of the scan
electrode Y, and the crossing portion only generates charges by a
discharge between the crossing portion and the address electrode
and is not required to accumulate wall charges. Therefore, part of
the scan electrode can be exposed to the discharge space and this
will lower the voltage needed to cause an address discharge to
occur. It is not necessary for the whole part of the crossing
portion of the scan electrode to be exposed, and it is preferable,
for example, to provide plural pores that connect the discharge
space and the scan electrode at the crossing portion of the scan
electrode.
[0025] It is also preferable to provide a common auxiliary
electrode and a scan auxiliary electrode that are connected to the
common electrode and the scan electrode, respectively, and widen
the common electrode and the scan electrode in the vicinity of the
crossing portion in order to make the gap constant. In this case,
if the surfaces of the common auxiliary electrode and the scan
auxiliary electrode are made to have the same depth from the
surface that comes into contact with the discharge space, the
thickness of the dielectric layer between the common electrode
provided downward and the surface can be reduced, and as a result,
the sustain discharge voltage can be reduced.
[0026] According to the present invention, as the address discharge
is limited to the crossing portion and the sustain discharge is
limited in the vicinity of the crossing portion, it is possible to
omit the partition wall that has been used conventionally, but it
is also possible to provide the partition wall. When the partition
wall is provided, it is preferable to provide on the surface of the
second substrate so as to separate the address electrodes, as
conventionally. This wall partition can also be used to define the
interval between the first substrate and the second substrate. It
is also preferable to make the partition lower and use it to
distinguish between the phosphors or to provide a spacer in
addition to such a low partition wall and use it to define the
interval between the substrates by combining them.
[0027] If the pixel pitch of the display screen in the horizontal
direction is to be made equal to that in the vertical direction,
the arrangement pitch of the scan electrode needs to be made equal
to those of the common electrode and the address electrode. In the
color display, however, R (red), G (green), and B (blue) phosphors
are formed in three adjacent display cells and a one-color pixel is
composed of these three display cells. It is preferable that the
one-color pixel has the same pixel pitch in the horizontal
direction as that in the vertical direction. Therefore, if a scan
pulse is applied to a group composed of the three adjacent scan
electrodes, the lit state or the unlit state of the three adjacent
display cells formed by the three adjacent scan electrodes can be
selected simultaneously by one scan pulse. Since the one-color
pixel is composed of 3.times.3, that is nine, display cells, the
pixel pitch in the horizontal direction and that in the vertical
direction become equal to each other.
[0028] It is also acceptable to make the arrangement pitch of the
scan electrode three times those of the common electrode and the
address electrode. In this case, a common auxiliary electrode and a
scan auxiliary electrode, for example, which extend in the same
direction of the common electrode and the address electrode are
provided, because it is necessary to extend the light emission
range (sustain discharge range) of each display cell in this
direction.
[0029] Moreover, by arranging the three pixels R, G, and B at the
vertexes of a grid, each grid unit of which is an equilateral
triangle, the pixel pitch of the one-color pixel in the horizontal
direction can be substantially made equal to that in the vertical
direction. In order to realize such an arrangement, the scan
electrode is made to turn in zigzag so that the crossing with the
common electrode forms a vertex.
[0030] It is preferable to be able to adjust the luminance
independently for each pixel of each color because each phosphor of
R, G, and B differs in light emission efficiency. Therefore, by
grouping the common electrode of each display cell by light
emission color to enable to drive each group independently, and by
setting independently the application period of the sustain pulse
to be applied in the sustain discharge period for each group, the
luminance and chromaticity can be adjusted for each color
pixel.
BRIEF DESCRIPTION OF THE DRAWINGS
[0031] The features and advantages of the invention will be more
clearly understood from the following description taken in
conjunction with the accompanying drawings, in which:
[0032] FIG. 1 is a rough plan view of the three-electrode surface
discharge AC type PDP.
[0033] FIG. 2 is a rough sectional view of the three-electrode
surface discharge AC type PDP.
[0034] FIG. 3 is a rough sectional view of the three-electrode
surface discharge AC type PDP.
[0035] FIG. 4 is a diagram that shows the fundamental structure of
the PDP apparatus of the present invention.
[0036] FIG. 5A through FIG. 5E are diagrams that illustrate the
operation of the PDP apparatus of the present invention.
[0037] FIG. 6A and FIG. 6B are diagrams that illustrate the
operation of the PDP apparatus of the present invention.
[0038] FIG. 7 is a block diagram that shows the rough structure of
the PDP apparatus in the embodiments of the present invention.
[0039] FIG. 8 is a diagram that shows the drive waveforms of each
electrode in the embodiments.
[0040] FIG. 9A and FIG. 9B are diagrams that show examples of the
PDP structure.
[0041] FIG. 10A and FIG. 10B are diagrams that show examples of the
electrode figure.
[0042] FIG. 11A through FIG. 11H are diagrams that show examples of
the electrode structure.
[0043] FIG. 12A and FIG. 12B are diagrams that show examples of
correspondence between the color pixels and the display cells.
[0044] FIG. 13 is a diagram that shows an example of the electrode
figure.
[0045] FIG. 14 is a diagram that shows an example of the color
pixel configuration and the electrode arrangement.
[0046] FIG. 15 is a diagram that shows an example of the color
pixel configuration and the electrode arrangement.
[0047] FIG. 16A through FIG. 16C are diagrams that show the drive
waveforms of the PDP apparatus shown in FIG. 15.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0048] FIG. 7 is a block diagram that shows the rough structure of
the PDP apparatus in the embodiments of the present invention. As
shown schematically, the PDP apparatus comprises a PDP 100 that has
the structure as shown in FIG. 4, a Y driver 101 that drives the Y
electrode, an X driver 104 that drives the X electrode, an address
driver 105 that drives the address electrode, and a control circuit
106. The Y driver 101 comprises a Y scan driver 102 and a Y common
driver 103. The control circuit 106 comprises a display data
control portion 107 and a panel drive control portion 109. The
display data control portion 107 comprises a frame memory 108. The
panel drive control portion 109 comprises a scan driver control
portion 110 and a common driver control portion 111. Except that
the PDP 100 has the structure as shown in FIG. 4, other parts of
the structure are almost the same as the conventional
three-electrode surface discharge AC type PDP apparatus, and each
driver can be realized as conventionally and, therefore, a detailed
description is omitted here.
[0049] FIG. 8 is a diagram that shows the drive waveforms in the
embodiments of the present invention, and AW is the waveform to be
applied to the address electrode A, XW is that to be applied to the
common electrode x, and YW is that to be applied to the scan
electrode Y. As shown schematically, the drive action is composed
of three periods, that is, a reset period, an address discharge
period, and a sustain discharge period as conventionally, and these
periods are repeated.
[0050] In the reset period, with a state in which 0 V is being
applied to the address electrode A, a pulse of voltage -Vq is
applied to the common electrode X and at the same time a
slope-shaped pulse, the voltage of which increases to Vw at a fixed
rate, is applied to the scan electrode Y to cause an erase
discharge to occur, then a pulse of voltage Vq is applied to the
common electrode X and at the same time a slope-shaped pulse, the
voltage of which decreases to a fixed negative voltage at a fixed
rate, is applied to the scan electrode Y to cause a neutralize
discharge to occur, thereby all the display cells are made to enter
a uniform state. By applying such a slope-shaped pulse, the
intensity of the erase discharge that lowers the contrast is
lowered and all the display cells are made to enter a uniform state
without fail.
[0051] Next, in the address discharge period, with a state in which
a voltage Vx is being applied to the common electrode X, a scan
pulse of voltage -Vy is applied sequentially to the scan electrode
Y and a write pulse of voltage Va is applied to the address
electrode A of a cell to be lit in synchronization with the
application of the scan pulse. In this way, a discharge is caused
to occur at the crossing portion of the address electrode A to
which the voltage Va has been applied and the scan electrode Y,
space charges are generated as shown in FIG. 5A and FIG. 5B, and
wall charges are accumulated with a distribution shown in FIG. 5E
according to the electric field formed between the common electrode
X to which the voltage Vx is being applied and the scan electrode Y
to which the scan pulse of voltage -Vy is being applied. By
performing such an action to every scan electrode Y by sequentially
applying a scan pulse, all the display cells are set to a state
corresponding to the display data.
[0052] In the next sustain discharge period, after a sustain pulse
of voltage Vs is applied to the scan electrode Y, a sustain pulse
is applied alternately to the common electrode X and the scan
electrode Y in this order. In this way, a sustain discharge is
caused to occur in the vicinity of the crossing portion of a cell
to be made to emit light as described in FIG. 6A and FIG. 6B, and
the display is performed. The above-mentioned reset period, address
discharge period, and sustain discharge period are repeated.
[0053] While the structure and the operation of the PDP apparatus
in the embodiments of the present invention have been described as
above, examples of the structure in the embodiments are described
in detail below.
[0054] According to the present invention, the address discharge is
limited to the crossing portion and the sustain discharge is
limited in the vicinity of the crossing portion, therefore, it is
possible to omit the partition wall used conventionally, but it is
also possible to provide the partition wall because of its role as
a spacer that defines the interval between the substrates. FIG. 9A
is a diagram that shows an example of the structure of a PDP that
has the partition wall. In this example, the common electrode X is
formed on the first substrate 34 made of glass, the scan electrode
Y is firmed thereon via the dielectric layer, and the dielectric
layer 35 is further provided on the surface thereof. On the other
hand, the address electrode A is formed on the second substrate 36
made of glass, a dielectric layer 40 is formed thereon, a partition
wall 318 is further formed between the address electrodes A, and a
phosphor 39 is formed therebetween. The partition wall 38 comes
into contact with the surface of the first substrate 34 and also
serves as a spacer that defines the thickness of the discharge
space 37. The phosphor 39 is excited by the discharge that occurs
in the discharge space 37 and emits light. Light can be emitted not
only from the first substrate 34 side on which the common electrode
X and the scan electrode Y have been formed (reflection type) but
also from the second substrate 36 side on which the phosphor 39 has
been formed (transparent type). The materials to form the common
electrode X, the scan electrode Y, and the address electrode A can
be transparent materials such as ITO or opaque metal materials, and
it is also acceptable that the electrodes made thereof are
combined. Either way, by providing the partition wall, the
propagation of the discharge can be more surely suppressed.
[0055] In FIG. 9B, the height of the partition wall 38 is decreased
and a space 41 is further provided in the structure shown in FIG.
9A. The partition 38 is used to distinguish among the phosphors 39.
In the present invention, it is not necessary to provide a
partition wall to prevent the propagation of the discharge, and
since the space 41 is required only to define the interval between
the substrates, it is not necessary to provide partition walls at
the same intervals as the partition walls 38, and the direction of
forming and the figures are arbitrary, but in FIG. 9B, the
partition wall 38 and the spacer 41 are overlapped with each other.
The spacer 41 can be provided, for example, at every several
partition walls, or between the scan electrodes Y so as to be
perpendicular to the partition wall. Moreover, the space 41 can
have not only a wall structure but also a cylindrical or a
spherical structure.
[0056] FIG. 10A and FIG. 10B are diagrams that show examples of the
electrode figure to which common auxiliary electrodes 43 and scan
auxiliary electrodes 42 to widen the common electrode X and the
scan electrode Y in the vicinity of the crossing portion are
provided. In the example of FIG. 10A, the auxiliary electrode is
formed so as to be a sector-shaped figure, the center of which
being at a point a little distance away from the crossing portion
of the common electrode x and the scan electrode Y and spreading
outward, and the common auxiliary electrode 43 and the scan
auxiliary electrode 42 are made so that their opposing radii are
parallel with a fixed gap G. Although the effects are the same
regardless of the materials of the auxiliary electrode, that is,
metal or transparent one, it is preferable to use the transparent
material for the reflection type because the light generated by the
phosphor 39 can pass therethrough. Moreover, although the auxiliary
electrode is provided to both the common electrode X and the scan
electrode Y in the example of the figure, it is also possible to
provide the auxiliary electrode to only one of the common electrode
X and the scan electrode Y. In the example of the figure, on the
other hand, the gap between the opposing radii of the common
auxiliary electrode 43 and the scan auxiliary electrode 42 is made
fixed, but it is also possible to employ a structure in which the
gap is not fixed and to suppress the instantaneous discharge
current by causing the discharge to occur scatteringly. Either way,
there are various examples of modification of the figures of the
auxiliary electrode.
[0057] In FIG. 10B, for example, the area of the auxiliary
electrode shown in FIG. 10A is reduced by removing the inner part
thereof. In this way, for the reflection type, the amount of the
emitted light that passes through can be improved and a sufficient
luminance can be obtained even if the auxiliary electrodes are
formed only by metal electrodes.
[0058] When the common auxiliary electrode 43 and the scan
auxiliary electrode 42 as described above are formed, the heights
of them are made equal to those of the common electrode X and the
scan electrode Y, respectively. FIG. 11A is a diagram that shows
the structure in this case, in which the common auxiliary electrode
43 is formed so as to be flush with the common electrode X and the
scan auxiliary electrode 42 is formed so as to be flush with the
scan electrode Y on the first substrate. In this case, the level of
the common auxiliary 43 is different from that of the scan
auxiliary electrode 42, and the common auxiliary electrode 43 is
larger in thickness with respect to the surface that comes into
contact with the discharge space 37. It is more preferable that the
thickness is smaller because the drive voltage can be less.
Therefore, as shown in FIG. 11B, the common auxiliary electrode 43
is formed so as to have the same level with the scan electrode Y
and the scan auxiliary electrode 42 by going round them, and is
connected to the common electrode X formed at a different
level.
[0059] In the structure shown in FIG. 4, since the scan electrode Y
and the common electrode X are arranged at the crossing portion via
the dielectric 35, the electrostatic capacity between the scan
electrode Y and the common electrode X becomes large and the drive
performance of the driver needs to be increased. Therefore, as
shown in FIG. 11C, the common electrode X is formed after a groove
is formed along the crossing portion or the portion where the scan
electrode Y is formed on the first substrate 34. Then a dielectric
layer 44 is formed so that the surface is flat and the scan
electrode Y and the dielectric layer 35 are formed thereon. In this
way, the electrostatic capacity at the crossing portion of the scan
electrode Y and the common electrode X can be reduced. If such a
structure is employed, it is possible to provide the scan electrode
Y and the common electrode X at the same level of those on the
first substrate except for the crossing portion.
[0060] As shown in FIG. 11D, on the other hand, after the common
electrode X is formed on the first substrate 34, a partition-shaped
structure 45 made of dielectric material is formed along the
crossing portion or the portion where the scan electrode Y is
formed, and the scan electrode Y is formed thereon. In this way,
the electrostatic capacity at the crossing portion of the scan
electrode Y and the common electrode X can be reduced and at the
same time the propagation of the discharge can be further
suppressed because the distance between the scan electrode Y and
the common electrode X increases. Moreover, it is possible to lower
the discharge start voltage by manufacturing the portion between
the common electrode X and the scan electrode Y of the crossing
portion using a material that easily emits electrons.
[0061] Still furthermore, as shown in FIG. 11E, by forming the scan
auxiliary electrode 42 on the side of the structure 45 in FIG. 11D,
the electrode gap between the scan electrode Y and the common
electrode X can be suppressed from excessively increasing, and an
adequate electrode gap can be obtained.
[0062] FIG. 11F is a diagram that shows an example, of an electrode
structure, in which a hole 46 is provided in the dielectric layer
35 on the crossing portion of the scan electrode Y so that the scan
electrode Y is exposed to the discharge space. The sustain
discharge is caused to occur only at a portion away a certain
distance from the crossing portion of the scan electrode Y, and the
crossing portion is required only to generate charges by a
discharge between the crossing portion and the address electrode A,
but not to accumulate wall charges. Therefore, part of the scan
electrode Y can be exposed to the discharge space, resulting in the
reduction in the voltage needed for the address discharge.
[0063] The whole of the crossing portion of the scan electrode does
not have to be exposed, and it is also acceptable that plural small
pores 47 are provided in the crossing portion of the scan electrode
Y so that part of the scan electrode Y is exposed to the discharge
space 37, as shown in FIG. 11G.
[0064] As shown in FIG. 11H, the voltage needed for the address
discharge can be also lowered, similarly, even if the address
electrode A is exposed to the discharge space 37.
[0065] FIG. 12A is a diagram that shows an example of
correspondence between the color pixels and the display cells in a
PDP apparatus that performs a color display. In this example, a
one-color pixel 51 is composed of the three display cells that are
formed along the scan electrode Y and adjacent horizontally, and
the phosphors R (red), G (green), and B (blue) are formed in the
three display cells, respectively. In the example of FIG. 12A, the
arrangement pitch of the scan electrode Y is the same as those of
the common electrode X and the address electrode A, and in the case
of monochrome display, the pixel pitch in the horizontal direction
is the same as that in the vertical direction, but the color pixel
pitch in the horizontal direction is three times that in the
vertical direction and the shape is like a horizontally wide
rectangle (a rectangle the width of which is much greater than its
length).
[0066] It is preferable for the color pixel to have the same pixel
pitch in the horizontal direction and in the vertical direction.
Therefore, if a scan pulse is applied, the three adjacent scan
electrodes Y being classified into one group, the lit state or the
unlit state of the three adjacent display cells formed by the three
adjacent scan electrodes can be simultaneously selected by one scan
pulse. In other words, the pixel of each color is composed of three
display cells adjacent vertically and the shape is like a
vertically extended rectangle (a rectangle the height of which is
much greater than its width). Since a one-color pixel is composed
of 3.times.3, that is nine, display cells, the color pixel pitch in
the horizontal direction is the same as that in the vertical
direction.
[0067] It is possible to make the color pixel pitch in the
horizontal direction equal to that in the vertical direction even
if the arrangement pitch of the scan electrode Y is made three
times those of the common electrode X and the address electrode A.
In the structure shown in FIG. 4 or FIG. 6A, however, in which the
common electrode X is perpendicular to the scan electrode Y, the
light emission area is almost circular and the density of display
cells in the vertical direction is lowered, therefore a problem,
that a sufficient luminance cannot be obtained, is caused.
Therefore, it is acceptable that the common auxiliary electrode 43
and the scan auxiliary electrode 42 that are vertically lengthened
are provided as shown in FIG. 13 so that the light emission area
has a shape of a vertically long rectangle can be obtained.
[0068] In these examples, the scan electrode Y extends linearly. In
FIG. 14, however, the scan electrodes Y are constructed so that the
scan electrode Y extends in zigzag, turning at the crossings of the
scan electrode Y and the common electrode X and the address
electrode Y, the successive three crossings being the vertexes of
an equilateral triangle. In the figure, the R pixel and the B pixel
are arranged on the upper side and the G pixel, on the lower side,
but in the case of a group in which pixels are horizontally
adjacent, the R pixel and the B pixel are arranged on the lower
side and the G pixel, on the upper side. In such a structure,
although a one-color pixel has a figure of an equilateral triangle,
it is possible to substantially make the pixel pitch of the
one-color pixel in the horizontal direction equal to that in the
vertical direction.
[0069] In the embodiments described so far, the common electrodes X
are commonly connected and it is assumed that the same drive
voltage is applied. On the contrary, in FIG. 15, the common
electrodes X are divided into three groups to be driven
independently: a common electrode group RX that forms the display
cell of the R pixel; a common electrode group GX that forms the
display cell of the G pixel; and a common electrode group BX that
forms the display cell of the B pixel. FIG. 16A through FIG. 16C
are diagrams that show examples of the drive waveforms in the
sustain discharge period that drive a PDP apparatus that has the
structure shown in FIG. 15, and FIG. 16A shows the drive waveforms
of the common electrode group RX, FIG. 16B shows those of the
common electrode group GX, FIG. 16C shows those of the common
electrode group BX, and an arrow indicates a discharge. As shown
schematically, the drive waveforms of the scan electrode Y are the
same and the number of times of sustain discharge in a fixed period
can be altered by varying the drive frequency of the common
electrode groups RX, GX, and BX. In this example, the ratio of the
number of times of sustain discharges in a fixed period for the
common electrode groups RX, GX, and BX is 1:1.5:2.
[0070] The light emission efficiency of each phosphor for R; G, and
B is different and if the ratio is assumed to be 2:1.5:1, the ratio
of the display luminance for each color will be the same when
driven at the same sustain discharge frequency, and this is not
preferable from the standpoint of color reproduction
characteristic. If the structure as shown in FIG. 15 is employed
and driven as shown in FIG. 16A through FIG. 16C, each term of the
display luminance ratio becomes identical for each color and the
color reproducibility can be improved.
[0071] As described above, according to the present invention, it
is possible to not only realize a PDP apparatus in which an
erroneous display due to the propagation of discharge is not caused
and the density of display cells is high, but also reduce power
consumption and costs because the range of each display cell can be
regulated by the structure of electrodes.
* * * * *